Effect of pederin on activity of digestive and detoxifying enzymes of Ephestia kuehniella (Lep: Pyralidae) and Tribolium confusum (Col: Tenebrionidae)

Amirmohammedi, Fereshteh; Bandani, Alireza; Amirheidari, Bagher; Sabahi, Qodratollah

doi:10.48311/jcp.2019.1414

Effect of pederin on activity of digestive and detoxifying enzymes of Ephestia kuehniella (Lep: Pyralidae) and Tribolium confusum (Col: Tenebrionidae)

https://doi.org/10.48311/jcp.2019.1414

Volume 8, Issue 1
March 2019

Pages 45-55

Document Type : Original Research

Authors

F. Amirmohammedi ¹

A. Bandani ¹

B. Amirheidari ²

Q. Sabahi ¹

¹ Department of Plant Protection, College of Agriculture and Natural Resources, University of Tehran, Iran.

² Pharmaceutics Research Center, Institute of Neuropharmacology, Kerman University of Medical Sciences, Kerman, Iran.

Abstract

During the last decade, plant and microbial-derived metabolites have received growing attention as potential tools for pest management in agriculture. Pederin (C₂₅H₄₅NO₉) is a vesicant toxin produced by Pseudomonas-like bacterial symbionts of rove beetles within the genus Paederus (Col: Staphylinidae). In this study, the toxicity of pederin to two stored product pests, Ephestia kuehniella Zeller (Lep: Pyralidae) and Tribolium confusum Jacquelin du Val (Col: Tenebrionidae) was evaluated using laboratory bioassays. Probit analysis estimated the median lethal concentrations of pederin as 1311.96 and 596.36ppm for E. kuehniella fourth larval instar and T. confusum adults, respectively. We also measured the activity of two major digestive enzymes (amylases and proteases) as well as three major detoxifying enzymes (P_450s monooxygenases, glutathione S-transferases, and carboxyl esterases) in insects treated orally with pederin. Feeding on pederin resulted in significant decrease in the activity of amylolytic, proteolytic, and carboxyl esterase enzymes, but significant increase in the activity of P_450s and glutathione S-transferases. Results of this study may highlight pederin as a novel source of pesticides with unique mode of action for use in pest management programs.

Keywords

digestive enzyme

Detoxifying Enzyme

Natural products

Paederus fuscipes

pederin

Toxin

20.1001.1.22519041.2019.8.1.2.2

Subjects

Insect Midgut and Digestive Enzymes

Abbott, W. 1925. A method of computing the effectiveness of an insecticide. J. econ. Entomol, 18(2), 265-267.
Aktar, W., Sengupta, D. and Chowdhury, A. 2009. Impact of pesticides use in agriculture: their benefits and hazards. Interdisciplinary toxicology, 2(1), 1-12.
Andrejko, M., Zdybicka-Barabas, A., Janczarek, M. and Cytryńska, M. 2013. Three Pseudomonas aeruginosa strains with different protease profiles. Acta Biochimica Polonica, 60(1).
Bell, C. and Savvidou, N. 1999. The toxicity of Vikane1 (sulfuryl fluoride) to age groups of eggs of the Mediterranean flour moth (Ephestia kuehniella). Journal of Stored Products Research, 35(3), 233-247.
Bernfeld, P. 1955. [17] Amylases, α and β.
Bowen, D. J. and Ensign, J. C. 1998. Purification and characterization of a high-molecular-weight insecticidal protein complex produced by the entomopathogenic bacteriumphotorhabdus luminescens. Applied and Environmental Microbiology, 64(8), 3029-3035.
Bradford, M. M. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical biochemistry, 72(1-2), 248-254.
Cantrell, C. L., Dayan, F. E. and Duke, S. O. 2012. Natural products as sources for new pesticides. Journal of Natural Products, 75(6), 1231-1242.
Carlini, C. R. and Grossi-de-Sá, M. F. 2002. Plant toxic proteins with insecticidal properties. A review on their potentialities as bioinsecticides. Toxicon, 40(11), 1515-1539.
Chan, Y. A., Podevels, A. M., Kevany, B. M. and Thomas, M. G. 2009. Biosynthesis of polyketide synthase extender units. Natural product reports, 26(1), 90-114.
Cox, P., Bell, C., Pearson, J. and Beirne, M. 1984. The effect of diapause on the tolerance of larvae of Ephestia kuehniella to methyl bromide and phosphine. Journal of stored products research, 20(4), 215-219.
Dayan, F. E. and Duke, S. O. 2014. Natural compounds as next-generation herbicides. Plant physiology, 166(3), 1090-1105.
Demain, A. L. and Fang, A. 2000. The natural functions of secondary metabolites. History of Modern Biotechnology I. Springer.
Desneux, N., Decourtye, A. and Delpuech, J.-M. 2007. The sublethal effects of pesticides on beneficial arthropods. Annu. Rev. Entomol., 52(81-106.
Duke, S. O., Cantrell, C. L., Meepagala, K. M., Wedge, D. E., Tabanca, N. and Schrader, K. K. 2010. Natural toxins for use in pest management. Toxins, 2(8), 1943-1962.
Elpidina, E. N., Vinokurov, K. S., Gromenko, V. A., Rudenskaya, Y. A., Dunaevsky, Y. E. and Zhuzhikov, D. P. 2001. Compartmentalization of proteinases and amylases in Nauphoeta cinerea midgut. Archives of Insect Biochemistry and Physiology, 48(4), 206-216.
Fields, P. G. and White, N. D. 2002. Alternatives to methyl bromide treatments for stored-product and quarantine insects. Annual Review of Entomology, 47(1), 331-359.
Gill, H. K. and Garg, H. 2014. Pesticides: environmental impacts and management strategies. Pesticides-Toxic Aspects. InTech.
Habig, W. H., Pabst, M. J. and Jakoby, W. B. 1974. Glutathione S-transferases the first enzymatic step in mercapturic acid formation. Journal of biological Chemistry, 249(22), 7130-7139.
Hinchliffe, S. J., Hares, M. C. and Dowling, A. J. 2010. Insecticidal toxins from the Photorhabdus and Xenorhabdus bacteria. The Open Toxinology Journal, 3(1).
Kellner, R. L. 1998. When do Paederus riparius rove beetles (Coleoptera: Staphylinidae) biosynthesize their unique hemolymph toxin pederin? Zeitschrift für Naturforschung C, 53(11-12), 1081-1086.
Kellner, R. L. 2002. Molecular identification of an endosymbiotic bacterium associated with pederin biosynthesis in Paederus sabaeus (Coleoptera: Staphylinidae). Insect Biochemistry and Molecular Biology, 32(4), 389-395.
Kellner, R. L. and Dettner, K. 1995. Allocation of pederin during lifetime ofPaederus rove beetles (Coleoptera: Staphylinidae): Evidence for polymorphism of hemolymph toxin. Journal of chemical ecology, 21(11), 1719-1733.
Kellner, R. L. and Dettner, K. 1996. Differential efficacy of toxic pederin in deterring potential arthropod predators of Paederus (Coleoptera: Staphylinidae) offspring. Oecologia, 107(3), 293-300.
Khandelwal, P., Choudhury, D., Birah, A., Reddy, M., Gupta, G. P. and Banerjee, N. 2004. Insecticidal pilin subunit from the insect pathogen Xenorhabdus nematophila. Journal of bacteriology, 186(19), 6465-6476.
Kumari, P., Mahapatro, G. K., Banerjee, N. and Sarin, N. B. 2015. A novel pilin subunit from Xenorhabdus nematophila, an insect pathogen, confers pest resistance in tobacco and tomato. Plant cell reports, 34(11), 1863-1872.
Lv, M., Wu, W. and Liu, H. 2014. Effects of fraxinellone on the midgut enzyme activities of the 5th instar larvae of oriental armyworm, mythimna separata walker. Toxins, 6(9), 2708-2718.
Mohseni, M., Haromar, S., Chaichi, M.-J. and Alijanpour-Toloti, S.-O. 2014. Dermatitis activity of pederin and isolation of endosymbiont bacterium associated with its biosynthesis from Paederus fuscipes beetle of Mazandaran, Iran. Journal of Mazandaran University of Medical Sciences, 23(2), 2-13.
Mosey, R. A. and Floreancig, P. E. 2012. Isolation, biological activity, synthesis, and medicinal chemistry of the pederin/mycalamide family of natural products. Natural product reports, 29(9), 980-995.
Panizzi, A. R. and Parra, J. R. 2012. Insect bioecology and nutrition for integrated pest management, CRC press.
Pavan, M. 1963. Ricerche biologiche e mediche su pederina e su estratti purificati di Paederus fuscipes Curt:(Coleoptera staphylinidae), Ponzio.
Phillips, T. W. and Throne, J. E. 2010. Biorational approaches to managing stored-product insects. Annual review of entomology, 55(
Piel, J. 2002. A polyketide synthase-peptide synthetase gene cluster from an uncultured bacterial symbiont of Paederus beetles. Proceedings of the National Academy of Sciences, 99(22), 14002-14007.
Piel, J., Höfer, I. and Hui, D. 2004. Evidence for a symbiosis island involved in horizontal acquisition of pederin biosynthetic capabilities by the bacterial symbiont of Paederus fuscipes beetles. Journal of bacteriology, 186(5), 1280-1286.
Pirajá da Silva, M. 1912. Le Paederus columbinus est vésicant. Arch Parasitol, 15(429-31.
Shao, L., Devenport, M. and Jacobs‐Lorena, M. 2001. The peritrophic matrix of hematophagous insects. Archives of insect biochemistry and physiology, 47(2), 119-125.
Stejskal, V. and Hubert, J. Arthropods as sources of contaminants of stored products: an overview. 9th International Working Conference on Stored Product Protection, 2006.
Subramanyam, B. 1995. Integrated management of insects in stored products, CRC Press.
Tabadkani, S. M. and Nozari, J. 2014. Relaxed predation hinders development of anti‐predator behaviors in an aposematic beetle. Entomologia experimentalis et applicata, 153(3), 199-206.
Van Asperen, K. 1962. A study of housefly esterases by means of a sensitive colorimetric method. Journal of insect physiology, 8(4), 401-416.
Wan, S., Wu, F., Rech, J. C., Green, M. E., Balachandran, R., Horne, W. S., Day, B. W. and Floreancig, P. E. 2011. Total synthesis and biological evaluation of pederin, psymberin, and highly potent analogs. Journal of the American Chemical Society, 133(41), 16668-16679.
WILLIAM, G. B. and JANET, C. 1997. Heme peroxidase activity measured in single mosquitoes identifies individuals expressing an elevated oxidase for insecticide resistance. Journal of the American Mosquito Control Association, 13(3), 233-237.

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